KR20170038051A - Plant growing system - Google Patents

Abstract

The present invention relates to a plant growth system for moving growing plants under active control, the plant growth system having the following characteristics: - a first guide panel center (10) and a first A first guide panel 1 having first guide panel slots 11 extending in the first guide panel 10 from an area adjacent to the guide panel center 10, An additional guide panel (2) having additional guide panel slots (21) providing guiding tracks for a plurality of plant fixation elements, wherein said first guide panel (10) with said first guide panel center 1) and said further guide panel (2) having a further guide panel center (20) are arranged concentrically and are applied on top of each other to provide rotational movement with respect to each other about a common axis of rotation (A) Plant fixation element Are formed at the intersections of said first guide panel slots (11) with said further guide panel slots (21), wherein according to a first principle said plant openings (O Like pattern in the rotational direction of the spiral-like pattern, and several or all of the spiral-adjacent plant openings O1 are distributed in the spiral-like pattern around the rotational axis A, A at the plant opening angle?. According to the invention, the first guide panel slots 11 and the further guide panel slots 21 are curved to form radial-adjacent plants 12 between the spiral-adjacent or circular-adjacent plant openings O1. The opening O2 is located outwardly on this branch of the opening angle alpha of the plant or is located at an angle less than 10 degrees, preferably less than 8 degrees, more preferably less than 6 degrees It is claimed to be located off the angle.

Description

PLANT GROWING SYSTEM [0002]

The present invention relates to a plant growth system for moving growing plants under positive control. Receiving active control means that the movement of growing plants is mechanically forced to follow the defined guiding track due to structural limitations.

Such a plant growth system is known from WO 87/06094 A1. This prior art plant growth system has the following features: a first guide panel having first guide panel slots and first guide panel slots extending in the first guide panel outwardly from a region adjacent to the first guide panel center, An additional guide panel having additional guide panel slots providing guide panels, additional guide panel centers and guiding tracks for a plurality of plant fixation elements. Wherein the first guide panel with the first guide panel center and the further guide panel with the further guide panel center are arranged concentrically and are applied on top of each other to provide rotational movement with respect to each other about a common axis of rotation , Wherein plant openings for the plant fixation elements are formed at the intersections of the first guide panel slots with the additional guide panel slots. Furthermore, according to a first principle, the first plant openings are distributed in a spiral-like pattern around the axis of rotation showing a sense of rotation, wherein several or all of the spiral-adjacent plants in the rotational direction of the spiral- Openings are arranged at plant opening angles with respect to the axis of rotation. As an alternative to the second principle, the plant openings are distributed in a number of circular-like patterns concentric to the axis of rotation, wherein several or all of the circular-adjacent plant openings on the same circular- At an angle of vegetable opening.

The advantage of the known plant growth system is that the distribution of adjacent plants showing different growth states is predetermined in only one direction. This structural boundary condition results in inefficient use of the space covered by the plant growth system.

It is therefore an object of the present invention to provide a plant growth system exhibiting improved efficiency.

This problem is solved by the plant growth system according to claim 1. According to the invention, the first guide panel slots and the further guide panel slots are curved so that radial-adjacent vegetation openings between the spiral-adjacent or circular-adjacent vegetation openings are separated from the second- Or less than 10 degrees, preferably less than 8 degrees, and more preferably less than 6 degrees from said line.

If the deviation from the claimed bisecting line is close to zero or zero, the use of space is optimized. This is because the spiral-adjacent or circular-adjacent plant openings show an arrangement of an isosceles triangular shape relative to the next radially adjacent plant opening in the outward direction visible from the common axis of rotation. As the deviation from this segment increases, the triangular arrangement is distorted from an increasingly perfect isosceles triangle scenario. However, the use of space between circular- / spiral-adjacent and radially adjacent plant openings is still more efficient due to the considerations claimed compared to conventional plant growth systems.

Plant openings are planted with plant capsules containing seeds and early growth material. These seeds will grow roots that extend to the surrounding environment. The plant growth system is arranged to provide nutrients to growing plant roots by methods known as hydroponic cultivation and / or aeroponic methods. Without being embedded in larger pieces of growth material, plants can easily be replaced on the itinerary from seed to harvest areas by replacing plant capsules that are subject to active control.

According to a preferred embodiment, the first guide panel slots have a first bend and the further guide panel slots are formed in a continuous spiral-like configuration when referring to the first principle. The characteristics of the spiral-like shapes include logarithmic spirals similar to perfect mathematical spirals, or shapes deviating from these perfect shapes, for example, by modified portions, as well as Archimedes spirals.

Alternatively, referring back to the second principle, the further guide panel slots are formed with curved slots with additional curvature extending from the area adjacent the center of the further guide panel outwardly into the further guide panel, The additional curvature is opposite to the first curvature of the first guide panel slots. The curvatures of the slots may all be uniform or variable.

In a preferred embodiment of the second principle, one of the first guide panel slots is mirror symmetrical with one of the further guide panel slots. This provides a desirable uniform distribution of plant openings in a circular pattern.

It is desirable that most or all of the additional bends of the additional guiding panel slots are the same to obtain a pattern to more effectively utilize the space for growing plants.

Referring to the first principle, the continuous spiral-like shape is adapted to the growth period of a particular plant species with respect to its bending, and with reference to the second principle, the first bend and the additional bend define a particular plant species It is suitable for the growth cycle. The travel time from the squeeze area to the harvest area around the center is defined according to the speed of relative rotation between the first guide panel and the further guide panel. Salads such as different plant varieties (eg Mordore, red cos, Lola Rosa and chocolate lettuce), Thai basil, Herbs such as Bonzai basil and wild oregano; tea herbs such as Melissa, cinnamon mint, pineapple sage and Verbena; Mizuma Stir fry greens such as Pak Choi, five color Swiss Chard and Turkish spinach, and Arugula, Mizuna, ) And Mustard) exhibit significantly different growth dynamics. These various specific dynamics are associated with the first guide panel slots < RTI ID = 0.0 > And the additional guidance By what you suitably change the curvature of all of the slot it can readily be satisfied in an optimal manner.

In another preferred embodiment, all of the plant opening angles have the same size. Again this highly symmetrical embodiment is most efficient in using the space provided for plants. For the same reasons it is advantageous that the plant growth system is characterized in that most or all of said first bends of said first guide panel slots are identical. Again, this feature increases symmetry and efficient use of space for growing plants.

To increase flexibility in the preferred embodiment, the plant growth system is arranged such that the first guide panel and the further guide panel are arranged in a removable manner, thereby allowing the possibility of combining different guide panels for different plant types . The size of the slots in the guide panels may vary depending on the variety. Furthermore, different panels can be provided depending on the solar-related growth rates of the seasons and plants.

In all of the above-mentioned embodiments, the first guide panel is formed in the form of a disk arranged to rotate about the rotation axis, wherein the additional guide panel is fixed relative to the rotation axis . Thereby, the further guide panel is fixed to the structure. Plant movement subject to active control is then caused by driving the first guide panel formed as a disc. The rotational movement of the first guide panel can be performed with the help of a motor of the driving member or manually. Further, the first guide panel has a circumference of a disk having a drive structure, which is arranged along the circumference of the disk and is engaged by a drive member for rotating the first guide panel around the axis of rotation . This drive structure may be provided as a cogwheel structure that provides mechanically robust and reliable solutions for driving the first guide panel in disc form. Embodiments with power units having drive members are advantageous because they allow for greater automation in plant growth systems. However, a low-budget personal user version can have a purely manual drive mechanism.

In all of the above-mentioned embodiments, the first guide panel and the further guide panel are disposed on a container, the container receiving plant roots controlled by the plant growth system and containing plant nutrients and / Plant roots. ≪ Desc / Clms Page number 2 > Preferably, the plant growth system according to claim 11 is characterized in that the container is arranged and applied as hydroponic cultivation and / or hydroponic cultivation plant growth apparatus.

Furthermore, a particularly advantageous embodiment is characterized in that the container according to the first principle shows a spiral-like channel structure with channel walls starting from the central region of the channel structure, or the container according to the second principle, And a channel structure extending from the central region of the structure and having several curved channels separated from each other by the channel walls. The channel walls prevent the roots of radially adjacent plants from contacting each other, which can cause stress to plants and exacerbate growth conditions.

In another embodiment, the plant growth system showing the channel structure and channel walls is characterized in that the channel structure exhibits an upward slope in a direction toward the central region of the channel structure. This slope allows water pumped to the central region to be flushed out of the channel structure using gravity.

In all embodiments of the plant growth system having the above-mentioned containers, the container is a control sensor device that detects variables from the group consisting of temperature, pH-value, plant fertilizer concentration and water level inside and outside the container . ≪ / RTI >

Furthermore, the control sensor device is preferably adapted to control the temperature inside the container, the pH-value, the plant fertilizer concentration and the water level. This control function is achieved by a heating and / or cooling device combined with pump systems which allow the required amounts of water, fertilizer and pH-equalizers to be provided.

In all plant growth systems according to any of the embodiments described above, the system preferably comprises a horticultural illumination device for illumination of the plants disposed above the first guide panel. Thereby, the system is independent of solar light and can be used indoors or even in areas without daylight. Furthermore, by the use of artificial light, the growth rate of the plants becomes easier to control by the lighting device. Preferably, such an illumination device comprises light emitting diodes which exhibit an emission spectrum particularly suitable for horticultural purposes. Valoya Oy, a manufacturer in Helsinki, Finland, is a desirable supplier of these LEDs.

Advantageously, the illumination device comprises a dimming device 51 for reducing illumination according to the degree of sunlight reaching the plant growth system. This characteristic helps reduce energy costs if the combined use of the lighting device and the sun is desirable.

If a lighting device is used, it is advantageous if the lighting device comprises a movable light source arranged to rotate about said axis of rotation. Compared to illumination with light sources that can not be moved relative to plants, this embodiment particularly helps to reduce energy costs. The movable light source may be attached at a distance closer to the plants. Thereby, the amount of light is remarkably improved.

In all of the plant growth system embodiments described above, the first guide panel, which is largely expanded or parallel to the common panel plane, and / or the additional guide panel is located at and around the center of the first guide panel It is advantageous if it shows outwardly extending and rising portions from the panel plane. If the plant growth system is about 60 cm or more in diameter, these elevated areas become easier to reach by those who operate the system.

The following several embodiments of the present invention are described in detail with reference to the corresponding drawings.
1 is a schematic top view of a first guide panel 1 in the form of a disc according to the first principle of the present invention.
2 is a schematic top view of a further guide panel 2 in the form of a disc according to the first principle of the invention.
Fig. 3 is a schematic top view of the superposition of the concentric axes of the first guide panel from Fig. 1 and the second guide panel from Fig. 2, the superposition being a plant distributed in a spiral-like pattern according to the first principle of the present invention Show openings.
Figure 4 is a schematic top view in which plants are arranged according to the first principle of the present invention.
5 is a first alternative embodiment of a spiral-like configuration of a further guide panel 2 with superposition of the concentric axes of the panels according to the first principle of the invention and the first guide panel 1;
Fig. 6 is a second alternative embodiment of the spiral-like configuration of the additional guide panel 2 with the superposition of the concentric axes of the panels and the first guide panel 1 according to the first principle of the invention.
7 is a schematic top view of a first guide panel 1 in the form of a disc according to the second principle of the present invention.
8 is a schematic top view of a further guide panel 1 in the form of a disc according to the second principle of the present invention.
Fig. 9 is a schematic top view of the superposition of the concentric axes of the first guide panel from Fig. 7 and the further guide panel from Fig. 8, which superimposition is achieved by a plant distributed in a circular- Show openings.
10 is a schematic top view in which plants are arranged according to the second principle of the present invention;
11 is a perspective view of a container 3 for receiving plant roots in hydroponic cultivation and / or hydroponic cultivation environments.
12 is a schematic perspective view of a plant growth system including a horticultural lighting apparatus 5. Fig.
Figure 13 is a schematic top view in which plants are arranged according to the first principle of the present invention including a movable light source.

Fig. 1 shows a schematic top view of a first guide panel 1 in the form of a disc according to the first principle of the present invention. The first guide panel 1 has a first guide panel center 10 having a rotation axis A passing through the center and the rotation axis A is a plane which is defined by the first guide panel 1 in the form of a flat disk, As shown in Fig.

Furthermore, in the first guide panel 1, a plurality of first guide panel slots 11 are evenly distributed on the disc-shaped structure. The first guide panel slots 11 all have the same curvature and each extend from a region adjacent to the first guide panel center 10 in the circumferential direction of the first guide panel.

The first guide panel 1 in the form of a disc is made of a suitable metal or plastic showing the drive structure 12 along its periphery. The drive structure 12 is formed as a periodic structure of teeth engaging by a gear wheel of the drive member 4. [ The first guide panel is rotated about the rotational axis A by the driving member 4. [

Figure 2 shows a schematic top view of a further guide panel 2 in the form of a disc in accordance with the first principle of the invention. The additional guiding panel 2 has an additional guiding panel center 20 with a rotational axis A passing through a center perpendicular to the plane defined by the further guiding panel. Further, the additional guide channel shows additional guide panel slots 21 formed in successive spiral shaped slots.

Figure 3 shows a schematic top view of the overlap of the first guide panel from Figure 1 and the concentric axis of the second guide panel from Figure 2; The same reference numerals denote the same elements with respect to FIGS. 1 and 2. Therefore, it is included without repetition as described. Both panels 1 and 2 exhibit the same rotational axis A and the overlap results in plant openings O distributed in a spiral-like pattern in accordance with the first principle of the present invention. The spiral-like pattern is defined by additional guide panel slots 21. The plant openings O appear where the additional guide panel slots 21 in the form of a spiral are superimposed by the first guide panel slots 11. Plant openings O adjacent to each other along an elongated helix shape are so-called helical-adjacent openings O1. In the rotational axis A, the pair of spiral-adjacent plant openings O1 are separated by the plant opening angle alpha. The next adjacent plant opening O in the radial direction along this division of the plant opening angle alpha is the radially-adjacent plant opening O2 lying on the so-called zonal. Further out in the radial direction from the radial-adjacent plant opening O2 the enveloping legs of the plant opening angle alpha pass through the further radial-adjacent plant openings O1 and the radially-adjacent plant openings O2 ) Will follow more along this line in the radial direction. The additional guiding panel slots 21 in the form of a spiral are formed as regular spirals and all the first guiding panel slots 11 showing the same shape and curvature are evenly distributed in the form of a disk. Therefore, all spiral-adjacent plant openings O1 are separated by the same plant opening angle alpha. This geometry utilizes the spacing space between plants growing along their own direction along additional guiding panel slots in the form of a spiral, which is roughly visible in Fig. Fig. 4 shows a schematic top view in which plants P are arranged according to the first principle of the present invention. Each circle following the helix and also of different diameters represents plants idealized at different growth stages. There is a plant opening (not shown) at the center of each circle. Higher efficiencies can be achieved over the same surface area as compared to plant growth systems known by optimized use of spacing space. Figure 4 shows how easily this plant growth system can be expanded and contracted.

5 shows a first alternate embodiment of the spiral-like configuration of the further guide panel 2 with the superposition of the concentric axes of the panels and the first guide panel 1 according to the first principle of the invention. The same reference numerals are used for the same elements. Therefore, reference is made to the following portions of the detailed description. Unlike the spiral form shown in FIG. 2, these additional spiral guide panel slots 21 do not follow an even path during all of their trajectories. The final part of the spiral after approximately four turns around the axis of rotation is further inclined to the periphery of the further guide panel 2 in the form of a disc. The last rotation of the helical-like additional guide panel slots 21 thereby turns close to the perimeter. This provides an easily accessible harvest area along more than 3/4 the circumference.

Fig. 6 shows a second alternative embodiment of the spiral-like configuration of the further guide panel 2 with the superposition of the concentric axes of the panels according to the first principle of the invention and the first guide panel 1; 5, the spiral-like configuration of the additional guiding panel slots 21 rotates around the rotational axis A three times before entering the harvesting area close to the perimeter. Depending on the growth characteristics of the particular plant species, the first guide panel 1 and the further guide panel 2 may be varied to obtain the necessary properties in space and time during the growth of the plants.

Fig. 7 shows a rough top view of the first guide panel 1 in the form of a disc according to the second principle of the present invention. This first guide panel 1 corresponds to the first guide panel shown in Fig. The only difference is the density of the first guide panel slots evenly distributed.

8 is a schematic top view of a further guide panel 1 in the form of a disc according to the second principle of the present invention. The additional guide panel 2 shows the same pattern of the arrangement in which the same sized slots, which are bent in the same manner as the first guide panel 1 shown in Fig. 7, are evenly distributed. However, the only difference is that the direction of bending of the additional guide panel slots 21 is opposite to the direction of bending of the first guide panel slots 11. Figure 9 shows a schematic top view of the overlap of the concentric axes of the first guide panel from Figure 7 and the further guide panel from Figure 8; This overlap shows plant openings (O) evenly distributed in a circular concentric circle in accordance with the second principle of the present invention. As seen from the axis of rotation A, the angle of the circle-adjacent vegetation opening O1 is the vegetation opening angle? As shown by two angle lags with this line. Beginning with this division between two circular-adjacent plant openings (O1) in the radial direction, this branch passes the radially-adjacent plant opening (O2). Unlike the first principle, according to the second principle plants do not rotate several times around the axis of rotation A during the growing time. The rotational overlap of the slots with opposite curvatures results in a curved path for each plant in its trajectory from the first guide panel center 10 to the periphery. The rotational movement of the two guide panels 1, 2 is significantly smaller compared to the first plant growth system principle.

Figure 10 shows an approximate top view in which plants are arranged according to the second principle of the present invention. Similar to Fig. 4, the spacing space between the approximate circle-shaped plants P is most efficiently utilized in this ideal arrangement. In Fig. 4, the growing plants (P) are arranged along a spiral path - in Fig. 10 the growing plants (P) are arranged in concentric circles provided as a system that can be easily scaled.

Figure 11 shows a perspective view of a container 3 for receiving plant roots in hydroponic and / or hydroponic cultivation environments. On this container, a first guide panel 1 and an additional guide panel 2 (not shown in Fig. 11) of the first principle shown in Figs. 1 and 2 are arranged. The container 3 may be a simple container which can, in the easiest case, sufficiently hold liquids such as water for a hydroponic cultivation system or steam for a hydroponic cultivation system. In this figure the container 3 is a more complex form showing a channel structure 30 with vertical walls 31. These walls isolate the roots of plants in different growth states that are structurally adjacent to each other on the spiral path but separated by a wall structure. In the spiral-shaped channels or in the middle, an inlet 33 for liquid or vapor is provided. An outlet 34 for liquid or vapor is provided near the perimeter. The bottom of the channel structure 30 from the inlet 33 to the outlet 34 shows a slope. In particular, in preferred hydroponics systems, water is moved from the inlet 33 to the outlet 34 along the spiral path by gravity. The control sensor device 32 is provided to monitor and control key parameters such as, for example, temperature, pH-value, fertilizer concentration, water level, and the like.

Fig. 12 shows a schematic perspective view of a plant growth system including a horticultural lighting apparatus 5. Fig. The illuminating device 5 is disposed on the container 3 covered by the first guide panel 1 and the further guide panel 2 of the first principle. Such a system can be placed in a rack and thereby be stacked vertically.

Figure 13 shows an approximate top view of the plants arranged in accordance with the first principle of the present invention with a movable light source 52. The movable light source 52 is a linear light source that extends radially outwardly from the rotation axis A. Rotating the light source 52 may be located much closer to the plants and may touch the plants P during rotation. The amount of light absorbed due to the shorter distance is larger compared to the static light source, which must cover all plants of different sizes over the entire time.

1: first guide panel 10: first guide panel center
11: first guide panel slots 12: drive structure
2: additional guiding panel 20: additional guiding panel center
21: Additional guide panel slots 3: Container
30: channel structure 31: channel walls
32: control sensor device 33: inlet
34: outlet 4: driving member
5: Garden lighting device 51: Photosensitive device
52: movable light source A: rotation axis
O: Plant openings
O1: Helix - adjacent plant openings / circle - adjacent plant openings
O2: Radial-adjacent plant openings
α: Plant opening angle

Claims (20)

In a plant growth system for moving growing plants under active control, the plant growth system has the following characteristics:
Having a first guide panel center (10) and first guide panel slots (11) extending in said first guide panel (10) from an area adjacent to said first guide panel center (10) The guide panel 1,
An additional guide panel 2 having an additional guide panel center 20 and additional guide panel slots 21 providing guiding tracks for a plurality of plant anchoring elements,
Wherein the first guide panel 1 with the first guide panel center 10 and the further guide panel 2 with the further guide panel center 20 are arranged concentrically and have a common axis of rotation A), and plant openings (O) for the plant anchoring elements are applied to the first guide panel slots (21) having the additional guide panel slots (21) 11, < / RTI >
According to a first principle, the plant openings O are distributed in a spiral-like pattern around the axis of rotation A showing the direction of rotation, and in the direction of rotation of the spiral-like pattern, several or all of the spiral- The adjacent plant openings O1 are arranged at plant opening angles? Relative to the axis of rotation A,
According to a second principle, the plant openings O are distributed in a number of circular-like patterns concentric to the axis of rotation A, wherein several or all of the circular-like patterns on the same circular- The plant openings O1 are arranged at plant opening angle? With respect to the axis of rotation A,
The first guide panel slots 11 and the further guide panel slots 21 are curved to form radial-adjacent vegetation openings O2 between the spiral-adjacent or circular-adjacent vegetation openings O1 Is located outwardly on this branch of the opening angle of the plant [alpha], or it deviates from this angle by less than 10 [deg.], Preferably less than 8 [deg.], More preferably less than 6 [ Plant growth system. The method of claim 1, wherein the first guide panel slots (11) have a first bend and refer to the first principle, the further guide panel slots (21) are formed in a continuous spiral- Or the second principle, the additional guiding panel slots 21 extend outwardly from an area adjacent to the further guiding panel center 20 with a further curved bend extending in the further guiding panel Wherein the additional curvature is opposite to the first curvature of the first guide panel slots (11). 3. Plant growth system according to claim 2, characterized in that one of the first guide panel slots is mirror-symmetrical to one of the further guide panel slots, again referring to the second principle. 4. Plant growth system according to claim 2 or 3, characterized in that most or all of said additional curvatures of said further guide panel slots (21) are identical. 3. The method of claim 2, wherein, referring to the first principle, the continuous spiral-like shape is adapted to a growth period of a particular plant species in its bend, and with reference to the second principle, Wherein the bend is adapted to the growth cycle of a particular plant species. 6. Plant growth system according to any one of claims 1 to 5, characterized in that most or all of the plant opening angles (?) Have the same size. 7. Plant growth system according to any one of claims 1 to 6, characterized in that most or all of the first bends of the first guide panel slots (11) are identical. 8. A method according to any one of the preceding claims, wherein the first guide panel (1) and the further guide panel (2) are arranged in a removable manner so that different guide panels for different plant types Wherein the plant growth system provides the possibility of binding. 9. A device according to any one of the preceding claims, wherein said first guide panel (1) is arranged to rotate about said axis of rotation (A), wherein said further guide panel (2) RTI ID = 0.0 > A). ≪ / RTI > 10. The apparatus according to claim 9, wherein the first guide panel (1) has a disk periphery having a drive structure (12), the drive structure (12) being arranged along the periphery of the disk Is adapted to be engaged by a drive member (4) to rotate the first guide panel (1). 11. Plant growth system according to any one of the preceding claims, characterized in that the first guide panel (1) and the further guide panel (2) are arranged on a container (3) Wherein the plant growth system is adapted to receive plant roots and / or provide plant nutrients and / or water to the plant roots. 12. Plant growth system according to claim 11, characterized in that the container (3) is arranged and applied as hydroponic and / or hydroponic cultivated plant growth apparatus. The container according to claim 11 or 12, wherein the container (3) according to the first principle shows a spiral-like channel structure (30) having channel walls (31) starting from a central region of the channel structure, Characterized in that the container (3) according to the second principle exhibits a channel structure with a number of curved channels extending from the central region of the channel structure in the outward direction and separated from each other by the channel walls (31) Growth system. 14. Plant growth system according to claim 13, characterized in that the channel structure (30) shows an upward slope in the direction towards the central region of the channel structure (30). 16. A method according to any one of claims 11 to 15, wherein the container (3) is adapted to detect variables from the group consisting of temperature, pH-value, plant fertilizer concentration and water level inside and outside the container And a control sensor device (32). 16. Plant growth system according to claim 15, characterized in that the control sensor device (32) is adapted to control the temperature inside the container (3), the pH-value, the plant fertilizer concentration and the water level. . 17. Plant growth according to any one of the preceding claims, characterized in that the system comprises a horticultural illumination device (5) for illumination of the plants placed on the first guide panel (1) system. 18. Plant growth system according to claim 17, characterized in that the illumination device (5) comprises a light-sensitive device (51) for reducing illumination according to the degree of sunlight reaching the plant growth system. 19. Plant growth system according to claim 17 or 18, characterized in that the illumination device (5) comprises a movable light source (52) arranged to rotate about the axis of rotation (A). 20. A device according to any one of the preceding claims, wherein the first guide panel (1) and / or the further guide panel (2), which is largely extended or parallel to the common panel plane, And that extend outwardly from the plane of the panel at and about the center (10).

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